Biochip reader with enhanced illumination and bioarray positioning apparatus

ABSTRACT

A method of illumination and illumination apparatus are provided in a biochip reader. Illumination is provided by a non-collimated laser source or a light emitting diode (LED). The light is directed to opposing sides of a glass substrate by a pair of optical fiber bundles. The glass substrate carries a bioarray. Each of the optical fiber bundles are splayed out to make a fan, the fan being one fiber thick and defining a line of optical fiber faces. This process randomizes any non-uniformity in the illumination source, creating a more uniform illumination source. A respective divergent diffuser engages each row of optical fiber faces coupling and diffusing light substantially evenly through the opposing sides of the glass substrate to illuminate the bioarray supported by the glass substrate. The glass substrate functions as a secondary light guide. The divergent diffusers separate the optical fiber faces from the edges of the glass substrate, protecting the optical fibers from mechanical damage. A glass holder supports the glass substrate carrying the bioarray. The glass holder including a plastics springs member in spring contact engagement with the glass substrate for positioning said bioarray in a focal plane. Light also can be directed to opposing ends of the glass substrate by a second pair of optical fiber bundles. Also a single optical fiber bundle can be used to direct light in one side of the glass substrate or three optical fiber bundles can be used to direct light into the glass substrate. This method of illumination provides a superior signal to noise ratio as compared with conventional illumination systems.

CONTRACTUAL ORIGIN OF THE INVENTION

The United States Government has rights in this invention pursuant to Contract No. W-31-109-ENG-38 between the United States Government and Argonne National Laboratory.

FIELD OF THE INVENTION

The present invention relates to a biochip reader having a novel method of illumination and improved illumination and bioarray positioning apparatus for enhanced quantitative analysis of biochip data.

DESCRIPTION OF THE RELATED ART

Analysis of biochip or bioarray data is carried out by the detection of the fluorescence from labeled target molecules that specifically interact with an immobilized array of molecular probes. The molecular probes may be attached directly onto a glass substrate or the probes may be attached onto a transparent plastic substrate. In an Argonne National Laboratory (ANL) 3D bioarray, the arrayed probes are attached to the glass substrate through a porous carrier which is chemically bound to the glass substrate.

One of the major problems in the quantitative analysis of bioarray data is finding a method of illumination of the array that is uniform over the area of the array to be analyzed. Any non-uniformity in the illumination translates into differences in the intensity of the fluorescence and thus tends to lead to erroneous results.

Another problem is positioning a glass substrate within an optical pathway so that the bioarray will be in the focal plane of a lens/lens array and within the field of view of the reader's optical system. Positioning the glass substrate has to be done repeatedly and with ease, without causing damage to the bioarray or the glass substrate. Positioning the glass substrate should not depend on the regular microscopic glass substrate thickness variation, typically, for example, 0.97 mm to 1.1 mm and also, length and width variations, length typically, for example, 75.513 mm to 76.2 mm, and width typically, for example, 24.638 mm to 25.552 mm. Information about commercially available microscope slides can be obtained, for example, at http://www.corning.com; and http://www.tedpella.com/histo_html/slides.htm. Positioning the glass substrate should not depend on whether or not a bioarray is covered with a reaction chamber. Reaction chamber information can be obtained, for example, at http://www.gracebio.com, http://www.eppendorf.com; http://www.mjr.com; and http://www.fishersci.com.

A need exists for an improved method of illumination and illumination apparatus to enable enhanced quantitative analysis of biochip data. It is desirable to provide such method of illumination and illumination apparatus that is effective and that is generally inexpensive, portable, lightweight, and simple to implement.

A need exists for an improved mechanism for positioning a glass substrate within an optical pathway so that the bioarray will be in the focal plane and within the field of view of an optical system. It is desirable to provide such an improved mechanism that is easy to use without causing any damage to the bioarray or the glass substrate.

SUMMARY OF THE INVENTION

A principal object of the present invention is to provide a biochip reader having an enhanced method of illumination and improved illumination and bioarray positioning apparatus enabling enhanced quantitative analysis of bioarray data. Other important objects of the present invention are to provide a method and apparatus for illumination in a biochip reader substantially without negative effect; and that overcome some disadvantages of prior art arrangements.

In brief, a novel method of illumination and illumination and bioarray positioning apparatus are provided in a biochip reader. Illumination is provided, for example, by a non-collimated laser source or a diode source. The light is directed to opposing sides of a glass substrate by a pair of optical fiber bundles. The glass substrate carries a bioarray. Each of the optical fiber bundles are splayed out to make a fan, the fan being one fiber thick and defining a line of optical fiber faces. This process randomizes any non-uniformity in the illumination source, creating a more uniform illumination of the bioarray. A respective divergent diffuser is provided proximate to each row of optical fiber faces coupling and diffusing light substantially evenly through the opposing sides of the glass substrate to illuminate the bioarray supported by the glass substrate.

The biochip reader includes illumination apparatus, a glass holder, and an optical system. The glass holder supports and aligns the glass substrate carrying the bioarray with the optical system. The glass holder includes a plastic springs member in contact engagement with the glass substrate with low contact forces for positioning the bioarray in a focal plane of the optical system.

In accordance with features of the invention, a manual positioner is coupled to the glass holder for simply positioning the bioarray within the field of view of an optical system. The divergent diffusers separate the optical fiber faces from the edges of the glass substrate, protecting the optical fibers from mechanical damage. A second function of the divergent diffusers is to reflect back outwardly going light to the glass to increase illumination efficiency. The glass substrate functions as a secondary light guide. The optical fiber bundles directing the laser light to the glass substrate are, for example, borosilicate fiber light guides. The optical fiber bundles also can be, for example, quartz, or plastic fiber light guides. Light also can be directed to opposing ends of the glass substrate by a second pair of optical fiber bundles. Also a single optical fiber bundle can be used to direct light in one side of the glass substrate or three optical fiber bundles can be used to direct light into the glass substrate. The method of illumination of the invention provides a superior signal to noise ratio as compared with conventional illumination systems.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention together with the above and other objects and advantages may best be understood from the following detailed description of the preferred embodiments of the invention illustrated in the drawings, wherein:

FIG. 1A is a schematic diagram representation illustrating biochip illumination apparatus for implementing the novel biochip method of illumination in accordance with the preferred embodiment;

FIGS. 1B, 1C, 1D, and 1E are detailed schematic diagram representations illustrating portions of the biochip illumination apparatus of FIG. 1A;

FIGS. 2A, 2B, 2C, 2D, and 2E are schematic diagram representations illustrating alternative biochip illumination arrangements in accordance with the preferred embodiment;

FIG. 3 is a perspective view of a glass holder for precisely positioning a glass supporting a biochip gel array used with the biochip illumination apparatus in accordance with the preferred embodiment;

FIG. 4 is a sectional view taken along line A—A of FIG. 3;

FIG. 5 is a sectional view taken along line B—B of FIG. 3; and

FIG. 6 illustrates a biochip reader including glass holder of FIG. 3 together with a positioner used with the biochip illumination apparatus in accordance with the preferred embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Having reference now to the drawings, FIG. 1 illustrates biochip illumination apparatus generally designated by the reference character 100 for implementing the novel biochip method of illumination in accordance with the preferred embodiment. Biochip illumination apparatus includes an illumination source 102.

Illumination is provided, for example, by a low power (3-5 mW) non-collimated laser diode 102 emitting at specific wavelength such as, between 470 nm and 650 nm. Alternatively, a light emitting diode (LED) coupled with optical filter can also be used as an illumination source 102. As an optical filter, standard filters can be used, for example: bandpass filters, longpass or shortpass barrier filters, and rejection band filters. For example, the following LED from the Newark catalog provides intensity equivalent to 5-10 mW: Super bright LED, green, 150 mcd, 50 deg, http://www.newark.com. An explanation how to translate mili-candela units to miliwatts can be found in the Basic Radiometry manual, http://www.opsci.com/technical.

As shown in FIG. 1A, a pair of fiber optic bundles 104 directs the light to opposing sides of a glass substrate 108. The glass substrate or slide 108 supports a biochip gel array or bioarray 110 including a plurality of biochip gel pads 112. The light is directed to the opposing sides of the glass substrate 108 by the fiber optic bundles 104 that are, for example, formed by borosilicate fiber light guides, quartz fiber light guides or plastic fiber light guides or fiber light guides formed by another suitable material.

Referring now to FIGS. 1A, 1B and 1C, the fiber optic bundles 104 are carried by a positioner 114 and are splayed out to make a respective fiber optic fan generally designated by the reference character 116. The fiber optic fans 116 are one fiber thick, each defining a light line 118 or linear array of a plurality of optical fibers 120. Each of the fiber optic bundles 104 includes a plurality of optical fibers 120 providing generally symmetrical illumination to the opposing sides of the glass substrate 108. A single fiber 120 is illustrated in FIG. 1C that is taken along line C—C of FIG. 1B. Each optical fiber 120 includes a polished face 122 positioned proximate to a divergent diffuser 124. The optical fiber fans 116 define the light line 118 of the plurality of optical fiber ends or faces 122 of the respective optical fibers 120 that are received within a window 126 of the divergent diffuser 124.

The polished optical fiber faces 122 defining the light line 118 transfer laser light to opposing sides 126 of the glass substrate 108 via the divergent diffuser 124 with only a small percentage of the laser light going back into the optical fiber 120. This illumination process of the preferred embodiment randomizes any non-uniformity in the laser source 102, creating a more uniform illumination source.

A thin line of light is coupled by the respective divergent diffusers 124 to illuminate the reacted bioarray 110 through a respective edge or sidewall 126 of the glass substrate 108 which diffuse light evenly and the bioarray is illuminated from the inside of the glass substrate 108. The glass substrate 108 functions as a secondary light guide. The sidewalls 126 of the glass substrate 108 diffuse light and are not polished. Typically, commercially available glass substrate or slides 108 are not polished and do not require any additional treatment to diffuse light. The divergent diffuser 124 provides mechanical protection for the polished faces 122 of the optical fibers 120. The divergent diffuser 124 reflects back outwardly going light to the glass 108 to increase illumination efficiency.

As shown in FIG. 1C, each optical fiber face 122 couples light through the divergent diffuser 124 at a restricted angle labeled Φ. The divergent diffuser 124 is formed of a silicon material. The divergent diffuser 124 is spaced apart from the sidewall 126 of the glass substrate 108, for example, by 600 microns. The restricted angle Φ of light transfer is for example, 55° to 60°. Multiple arrows labeled A indicate light diffusion or mixing from each optical fiber face 122 coupled to the edge 126 of the glass substrate 108.

Referring now to FIG. 1D, opposite fiber optic fans 116 are shown with the glass substrate 108. As indicated by arrows labeled R, the respective centers of sequential fibers 120 of the opposite fiber optic fans 116 are offset or shifted by one radius size. This offset arrangement of the opposite fiber optic fans 116 improves light distribution within the glass substrate 108.

Referring now to FIG. 1E, a reflector 150 can be provided to reflect outwardly going light back to the glass substrate 108 and thus avoid loss of light during illumination. One or more reflectors 150 can be provided proximate to one or more respective ends 152 or endwalls of the glass substrate 108 that are spaced apart and separate from the divergent diffusers 124 or fiber optic fans 116. For example, the reflector 150 can be similar to the divergent diffuser 124 having generally the same restricted angle Φ of light reflection but without the open window 126.

FIGS. 2A, 2B, 2C, 2D, and 2E illustrate alternative biochip illumination arrangements in accordance with the preferred embodiment. The same reference numbers as used with illumination apparatus 100 of FIGS. 1A and 1B are used for similar or identical components in FIGS. 2A, 2B, 2C, 2D, and 2E. As shown in FIGS. 2A, 2B, 2C, 2D, and 2E, the present invention is not limited to the use of a single pair of optical fiber bundles 116 to direct the light into opposing sides of the glass substrate 108. A second pair of optical fiber bundle fans 116 can be provided to direct the light into opposing ends of the glass substrate 108; or a single optical fiber bundle fan 116 or three optical fiber bundles 116 can be provided to direct the light into the glass substrate 108. The number of optical fiber bundle fans 116 provided depends on the size of an area of the glass substrate 108 that needs to be illuminated. In general, the entire perimeter of the glass substrate 108 including both opposing sides and both opposing ends, advantageously can be illuminated to obtain maximum uniformity.

Referring to FIG. 2A, there is shown illumination apparatus generally designated by the reference character 200 for implementing the novel biochip method of illumination in accordance with the preferred embodiment. Illumination apparatus 200 includes a pair of fiber optic fans 116 on opposing sides of glass substrate 108 with a respective light source 102 coupled to each fiber optic fan 116.

Referring to FIG. 2B, there is shown illumination apparatus generally designated by the reference character 210 for implementing the novel biochip method of illumination in accordance with the preferred embodiment. Illumination apparatus 210 includes a first pair of fiber optic fans 116 on opposing sides of glass substrate 108 and a second pair of fiber optic fans 116 on opposing ends of glass substrate 108 with a respective light source 102 coupled to each fiber optic fan 116.

Referring to FIG. 2C, there is shown illumination apparatus generally designated by the reference character 220 for implementing the novel biochip method of illumination in accordance with the preferred embodiment. Illumination apparatus 220 includes a pair of fiber optic fans 116 on opposing ends of glass substrate 108 and a fiber optic fan 116 on one side of glass substrate 108 with a respective light source 102 coupled to each fiber optic fan 116.

Referring to FIG. 2D, there is shown illumination apparatus generally designated by the reference character 240 for implementing the novel biochip method of illumination in accordance with the preferred embodiment. Illumination apparatus 240 includes a first fiber optic fan 116 on one side of glass substrate 108 and a second fiber optic fan 116 on one end of glass substrate 108 with a respective light source 102 coupled to each fiber optic fan 116.

Referring to FIG. 2E, there is shown illumination apparatus generally designated by the reference character 250 for implementing the novel biochip method of illumination in accordance with the preferred embodiment. Illumination apparatus 250 includes a single fiber optic fan 116 on one side of glass substrate 108 with a light source 102 coupled to the fiber optic fan 116.

It should be understood that in each illumination apparatus 100, 200, 210, 220, 240, and 250, various low power lasers or light emitting diodes (LEDs) can be used for as the illumination source 102. Lasers 102 having different wavelength can be used in illumination apparatus 200, 210, 220, and 240. The different wavelength lasers 102 can be used sequentially depending upon a particular target's label.

Referring now to FIGS. 3, 4 and 5, there is shown a glass holder generally designated by the reference character 300 in accordance with the preferred embodiment for precisely positioning the glass 108 supporting multiple biochip gel arrays. Glass holder 300 includes a support housing 302 including opposing sidewalls 304, 306 and opposing front and rear walls 308, 310. Glass holder includes a glass-receiving cavity 312 including a bottom surface 314 carrying a rectangular plastic springs member 316. A Velcro material advantageously forms the plastic springs member 316. The glass 108 sits on the plastic springs member 316 with low contact force. A pair of spring loaded rollers 320, 322 and an axis member 324 are mounted within an upper surface 326 of the glass holder support housing 302 engaging the glass 108 with a low contact force. The glass 108 supporting the biochip gel array is easily inserted into and removed from the glass-receiving cavity 312 carried by the plastic springs member 316. The plastic springs member 316 pushes up on the glass 108 providing an effective focal plane for reading a particular biochip gel array carried by the glass 108. Glass holder 300 can be used with the bioarray carried by the glass substrate 108 when covered or not covered with a reaction chamber and the bioarray is provided in the focal plane of an optical system.

In accordance with features of the invention, this method of illumination provides a significantly improved illumination of the biochip gel pads 112 within the biochip array 110. This method of illumination provides a superior signal to noise ratio as compared with conventional illumination systems.

Two variants of bioarray illumination were modeled and tested for comparison of the illumination of the invention with conventional biochip illumination. The first variant of bioarray illumination uses conventional biochip illumination where the light beams from laser hit the bioarray directly from above the biochip array. The second uses the illumination apparatus 100 of the preferred embodiment including an intermediate fiber light guide (touch-to-line) which transmits light through diffuser 122 and the side 126 of the glass substrate 108 into the glass substrate, so that the light illuminates the bioarray 110 from inside of the glass substrate. The glass substrate 108 is used as the secondary light guide in accordance with the preferred embodiment.

For both types of illumination, the uniformity was measured using fluorescent signal from empty glass. Two images was acquired: with exposure time equal to 3 seconds for the first scheme and with exposure time equal to 20 seconds for the second scheme. The exposure times were selected so that the fluorescent intensities are generally of the same order. Additional acquisition was taken for each scheme without illumination with the same exposure time to subtract the dark current of a charge coupled device (CCD) camera.

The following tables A and B contain average fluorescent signal respectively collected from small areas of image arranged into grid using conventional illumination and with illumination apparatus 100 of the preferred embodiment. The value is calculated as the sum of pixel intensities divided by the square of the area.

(For the first scheme conventional light from above the biochip array, 3 seconds, dark current subtraction):

TABLE A with conventional illumination apparatus 8.406 8.722 8.958 8.917 9.06 9.152 8.679 8.241 7.651 7.096 6.661 9.982 12.75 11.91 12.038 11.283 12.452 12.008 10.429 9.749 10.752 7.822 11.365 12.925 13.325 14.794 13.584 14.366 14.071 12.755 12.285 11.35 9.785 12.665 14.39 14.454 14.865 16.615 15.393 14.814 14.234 13.722 15.4 10.668 13.706 15.273 16.175 17.614 16.928 17.232 16.138 15.468 17.111 15.264 11.693 14.429 16.654 17.268 18.605 17.651 16.716 15.824 16.161 15.572 14.222 11.751 14.338 16.796 17.336 19.784 16.818 15.992 15.019 15.012 14.484 13.326 11.247 13.254 15.569 16.563 17.343 15.858 15.185 14.402 14.591 13.589 12.711 10.725 11.083 12.71 13.159 14.05 13.404 12.079 11.848 11.86 10.863 11.196 8.951 9.542 9.434 10.572 10.921 10.221 10.063 9.276 8.938 8.693 8.056 7.306

(For the second illumination scheme in accordance with the preferred embodiment with illumination light from sides, 20 seconds, dark current subtraction):

TABLE B with illumination apparatus 100 5.416 6.339 6.462 6.941 6.96 6.97 7.213 6.978 7.128 7.238 6.881 5.502 7.246 6.923 7.487 7.107 7.879 7.595 7.199 7.324 9.082 7.048 6.158 7.021 6.969 7.455 7.353 7.331 7.469 7.302 7.479 7.406 7.094 6.515 7.44 7.065 7.066 7.382 7.145 7.236 7.411 7.534 8.124 7.352 6.523 7.475 7.208 7.53 7.242 7.494 7.463 7.474 7.797 7.953 6.847 7.103 7.755 7.678 7.815 7.547 7.48 7.182 7.335 7.458 7.375 6.982 7.18 7.947 7.579 8.073 7.451 7.276 7.175 7.28 7.328 7.301 7.15 7.148 8.011 7.96 7.678 7.798 7.482 7.484 7.328 7.102 7.178 6.902 7.498 7.792 7.967 8.112 7.654 7.216 7.09 7.384 7.382 7.216 6.903 6.945 7.694 7.593 7.383 7.405 7.445 7.602 7.585 7.041 6.909 6.833

The purpose of biochip reader is to measure fluorescent signals acquired from different pads of a microarray. Unevenness of illumination is one of the major sources of error in measurements. When the fluorescent signals are greater enough than the noise of CCD camera, the non-uniformity of illumination is the only source of error in such measurements.

Consider the relative standard deviation (RSD), defined as the standard deviation divided by the average value, is a measure of the uniformity of illumination. The RSD is the simplest criteria that reflect the quality of illumination. The uniformity of illumination is better and the error is less when the RSD is less.

Average Standard value deviation RSD First scheme 12.92877 3.005968 0.23 Second scheme 7.303645 0.471795 0.064

On basis of data analysis the second scheme of illumination with illumination apparatus 100 of the preferred embodiment provides 3.6 times better uniformity and correspondingly 3.6 times less error than the first conventional illumination scheme.

Referring to FIG. 6, a biochip reader generally designated by the reference character 600 includes biochip illumination apparatus 100, the glass holder 300 together with a manual positioner generally designated by the reference character 602 in accordance with the preferred embodiment. Biochip reader 600 is generally inexpensive, portable, lightweight, and simple to implement. Biochip reader 600 is illustrated in simplified form sufficient for understanding the present invention.

Biochip reader 600 includes a charge coupled device (CCD) camera 604, a lens/lens array 606, and a filter 608. The CCD camera 604 and associated lens/lens array 606 and filter 608 are aligned with a window 610 in a first plate 612. A centerline through the window 610 and the CCD camera 604 and associated lens/lens array 606 and filter 608 is labeled CL. In the biochip reader 600, the glass holder 300 includes the plastic springs member 316 as seen in FIG. 3 that pushes up on the glass 108 with low contact forces providing an effective focal plane for reading a particular one of two biochip gel arrays 614, 616 carried by the glass 108. A light guide, fiber optic fan 116 is disposed proximate to the glass substrate 108 generally aligned with the window 610. The manual positioner 602 includes a first ball bearing slide 620 coupled to a plate 618 and to the glass holder 300 and a second ball bearing slide 622 coupled to a stationary second plate 624. The manual positioner 602 includes a base plate 626 supporting plates 612 and 624. The manual positioner 602 includes a lever 628 extending through a slot (not shown) in the stationary second plate 624 and is mounted to the plate 618. A plunger pin 634 also is mounted to plate 618. A pair of stop points 630 and 632 is formed within the second plate 624 for engagement with the plunger pin 634 of the manual positioner 602. The lever 628 is manually moved, moving the ball bearing slide 620, plate 618, plunger pin 634, and the glass holder 300 and the glass substrate 108 carrying the two biochip gel arrays 614, 616.

As shown in FIG. 6, the plunger pin 634 is received within the stop point 630, the biochip gel array 616 is aligned with window 610 for reading. When the lever 628 of manual positioner 602 is slidingly moved to position the plunger pin 634 with the stop point 632, the biochip gel array 614 is aligned with window 610 for reading. Biochip reader 600 includes a case 640 and a hood 642 containing the manual positioner 602, glass holder 300, the CCD camera 604 and associated lens/lens array 606 and filter 608.

In order to evaluate the use of biochip reader 600 for registration of fluorescent signals from biochips manufactured with use of different commercially available glass slides, the following experiment was carried out. Biochips containing a set of probes were produced by using slides from Motorola (3D-Link), Telechem (Superaldehyde), and Packard Bioscience (Hydrogel), as indicated in the following Tables 1 and 2. After the application of oligonucleotides bearing 5′-end amino group, the immobilization was carried out according to procedures recommended by the manufacturers.

Hybridizations with a mix of Texas Red labeled target oligonucleotides (5 fmol/μl) (Table 3) were carried for 4 h at 25° C. in 200-μl hybridization chamber (Grace Biolabs). Hybridization buffer contained 1 M guanidine isothiocyanate, 50 mM HEPES (pH 7.5), and 10 mM EDTA. After hybridization the biochips were washed for 30 sec with 6×SSPE with 0.1% Triton X-100, washed for 5 sec with MilliQ water, and dried. Hybridization signals from the biochips were recorded on the biochip reader 600 and on a commercially available scanner, Model: Bio-Chip Imager, Part No.: 902-3013001 manufactured by Packard Instrument Company, Inc., now it is Packard Bioscience.

The fluorescence intensities data was analyzed using two methods. First, the correlation function was calculated for all biochip elements of 4 chips located on slide, separately for different slide types. The correlation function is defined, for X[i] and Y[i], as M((x-Mx)(y-My))/(MxMy), where M is average of its argument array. The feature of the correlation function is that it equals 1 when and only when X and Y arrays are congruent. Since the signal is proportional to the amount of fluorescent substance, the correlation in readings between the biochip reader 600 and the scanner shows the ability of the biochip reader 600 to acquire these signals.

In the second calculation, 4 groups of biochip elements are considered: bare glass, probes that do not hybridize, probes that show hybridization with labeled target, and biochip elements with pre-immobilized labeled oligonucleotides used as markers. Correlation of average signals from all 4 types of biochip elements is also calculated for all slide types.

Table 4 summarizes data for correlation between fluorescent signals recorded by the biochip reader 600 and the scanner. For all biochips the correlation between fluorescent intensities acquired by the biochip reader 600 and the scanner is positive, and is greater than 0.9 when calculated for different types of biochip elements. This data shows the applicability of the biochip reader 600 for measurement of fluorescent signals from commercially available biochips and biochips manufactured with use of different commercially available glass slides.

TABLE 1 Scheme for probe location for the biochip 1004 1005 1004 1005 1 11 21 31 41 51 2 12 22 32 42 52 3 13 23 33 43 52 4 14 24 34 44 52 5 15 25 35 45 52 6 16 26 36 46 52 7 17 27 37 47 52 8 18 28 38 48 9 19 29 39 49 52 10 20 30 40 50 52 1 11 21 31 41 51 2 12 22 32 42 52 3 13 23 33 43 52 4 14 24 34 44 52 5 15 25 35 45 52 6 16 26 36 46 52 7 17 27 37 47 52 8 18 28 38 48 9 19 29 39 49 52 10 20 30 40 50 52 1004 1005

TABLE 2 List of oligonucleotide probes used for biochip manufacturing Solution # Contents (Sequence) C, mM 1 CTTTRGAAAATAIGAGATAATT 1 2 TTGAGTAAATAGGRTATAATTG 1 3 TTGAGTARATAAGATATAACTG 1 4 TTACCCGATTCCRGGTTAATT 1 5 TTACCCGATTCTRGGTTAATT 1 6 GAGGRTAYACGAATTACTAC 1 7 GTATTTCCGCATTGTGAYGC 1 8 GTATTTTCGCATTGAGAYGC 1 9 TATACGTTCGTGTGCAGT 1 10 GTAAATCTGTTCTATGCTGT 1 11 CTTAARAAAACGAGTGATAATT 1 12 YCTGTTACAGTGTTTAATAGTTT 1 13 AAACTTGYCAAAGCTGTYAGA 1 14 TTGATAATTRCATTACGGCTA 1 15 TTGATAATCACATTRCGGCTA 1 16 TAATIAYGAGACTTCTCCAGT 1 17 TTTTACGATTGCCTTTYTGGATA 1 18 GTTATAATGATTGTAGTATCC 1 19 TTGAATTGAATARTTCGTAGT 1 20 GTTATAATGATTGTAGTATCC 1 21 TTGAATTGAATARTTCGTAGT 1 22 AAATGCTAAGCATGAATATGG 1 23 AGATGCTAAGCAYGAGTATGG 1 24 AGTCITGATAATAYTTGGAYGTA 1 25 TTTCTAATACATSGGTIAATTTGAG 1 26 ATAGGCAATGGGRCTGATA 1 27 GITTATTTGCAGTTAARGGG 1 28 GTTTATTCGCAGTTAARGGG 1 29 CACTGTTGTAGCAAATAGG 1 30 TCGTTTAGAGGTGACGTCYT 1 31 RCATAAATATAAACATAGTGTG 1 32 ACCTAAAATCACGCAAAGGATATCAA 1 33 ATYGATATTRCATCRTTAACAAG 1 34 AAAAYCATCTGAYTAATTATTCTATA 1 35 TCACAATAATTTAAAATGCTCT 1 36 GTCGTCAATAGCATTAATAATAC 1 37 GTAGCCAATAGCGTTAATAATA 1 38 GATGCTAATGATATATTTCCATA 1 39 ACRTTCTATTGTGAAGGTGCYTC 1 40 ATATTTCAAGCYCCATAGTAG 1 41 GAGTGCCCTAATCCAGTG 1 42 CTGTGTTCTTAGGTATTATG 1 43 ATTGCTTACGGAGGTGATTTTG 1 44 ATCATTTCCATGTAGAGTTGC 1 45 TCTTYTGCACCCTARTCYATTTGA 1 46 GTYCAATTCTACCTTCTATGA 1 47 GACTTGRAGAGGTACRTTTTC 1 48 GACTTGGAGAAGTACATTTTC 1 49 GCATTRCTTCTCTGAATGAAT 1 50 AGTTAGTTGTAATCCACTATAC 1 51 ATTTTGCGATCAATATACACAT 1 52 GATGATGATGATGATGATGA 2 1004 TR-TTTTTTTT-NH2 0.1 1005 TMR-TTTTTTTT-NH2 0.1 Sequences Listed from 5′ to 3′ All oligos contain 5′ C6 NH2 IUPAC Nucleotide designations M A/C R A/G Y C/T W A/T S C/G K G/T V A/G/C H A/C/T D A/G/T B C/G/T N A/G/C/T I Inosine

TABLE 3 Sequences of target oligonucleotides and complimentary probes and probe numbers Number of probe Sequence of complementary probe (5′ on a Sequence of target (5′ −> 3′) −> 3′) biochip CAATTATAYCCTATTTACTCAA TTGAGTAAATAGGRTATAATTG 2 T(5)-AATTAACCYAGAATCGGGTAA-T(5) TTACCCGATTCTRGGTTAATT 5 T(15)-TCTRACAGCTTTGRCAAGTTT-T(15) AAACTTGYCAAAGCTGTYAGA 13 TATCAGYCCCATTGCCTAT ATAGGCAATGGGRCTGATA 26 CCCYTTAACTGCGAATAAAC GTTTATTCGCAGTTAARGGG 28 T(20)-CCTATTTGCTACAACAGTG-T(20) CACTGTTGTAGCAAATAGG 29 ARGACGTCACCTCTAAACGA TCGTTTAGAGGTGACGTCYT 30 CTTGTTAAYGATGYAATATCRAT ATYGATATTRCATCRTTAACAAG 33 T(10)-TCAAATRGAYTAGGGTGCARAAGA-T(10) TCTTYTGCACCCTARTCYATTTGA 45 GTATAGTGGATTACAACTAACT AGTTAGTTGTAATCCACTATAC 50 CAATTATAYCCTATTTACTCAA GATGATGATGATGATGATGA 52

TABLE 4 Correlation for biochips acquired by Reader and scanner Correlation for all Slide Manufacturer elements Correlation for groups Motorola 0.87 0.99 Packard 0.81 0.92 Telechem 0.61 0.99

While the present invention has been described with reference to the details of the embodiments of the invention shown in the drawing, these details are not intended to limit the scope of the invention as claimed in the appended claims.

74 1 22 DNA Artificial Completely Synthesized 1 ctttrgaaaa tangagataa tt 22 2 22 DNA Artificial Completely Synthesized 2 ttgagtaaat aggrtataat tg 22 3 22 DNA Artificial Completely Synthesized 3 ttgagtarat aagatataac tg 22 4 21 DNA Artificial Completely Synthesized 4 ttacccgatt ccrggttaat t 21 5 21 DNA Artificial Completely Synthesized 5 ttacccgatt ctrggttaat t 21 6 20 DNA Artificial Completely Synthesized 6 gaggrtayac gaattactac 20 7 20 DNA Artificial Completely Synthesized 7 gtatttccgc attgtgaygc 20 8 20 DNA Artificial Completely Synthesized 8 gtattttcgc attgagaygc 20 9 18 DNA Artificial Completely Synthesized 9 tatacgttcg tgtgcagt 18 10 20 DNA Artificial Completely Synthesized 10 gtaaatctgt tctatgctgt 20 11 22 DNA Artificial Completely Synthesized 11 cttaaraaaa cgagtgataa tt 22 12 23 DNA Artificial Completely Synthesized 12 yctgttacag tgtttaatag ttt 23 13 21 DNA Artificial Completely Synthesized 13 aaacttgyca aagctgtyag a 21 14 21 DNA Artificial Completely Synthesized 14 ttgataattr cattacggct a 21 15 21 DNA Artificial Completely Synthesized 15 ttgataatca cattrcggct a 21 16 21 DNA Artificial Completely Synthesized 16 taatnaygag acttctccag t 21 17 23 DNA Artificial Completely Synthesized 17 ttttacgatt gcctttytgg ata 23 18 21 DNA Artificial Completely Synthesized 18 gttataatga ttgtagtatc c 21 19 21 DNA Artificial Completely Synthesized 19 ttgaattgaa tarttcgtag t 21 20 21 DNA Artificial Completely Synthesized 20 gttataatga ttgtagtatc c 21 21 21 DNA Artificial Completely Synthesized 21 ttgaattgaa tarttcgtag t 21 22 21 DNA Artificial Completely Synthesized 22 aaatgctaag catgaatatg g 21 23 21 DNA Artificial Completely Synthesized 23 agatgctaag caygagtatg g 21 24 23 DNA Artificial Completely Synthesized 24 agtcntgata atayttggay gta 23 25 25 DNA Artificial Completely Synthesized 25 tttctaatac atsggtnaat ttgag 25 26 19 DNA Artificial Completely Synthesized 26 ataggcaatg ggrctgata 19 27 20 DNA Artificial Completely Synthesized 27 gnttatttgc agttaarggg 20 28 20 DNA Artificial Completely Synthesized 28 gtttattcgc agttaarggg 20 29 19 DNA Artificial Completely Synthesized 29 cactgttgta gcaaatagg 19 30 20 DNA Artificial Completely Synthesized 30 tcgtttagag gtgacgtcyt 20 31 22 DNA Artificial Completely Synthesized 31 rcataaatat aaacatagtg tg 22 32 26 DNA Artificial Completely Synthesized 32 acctaaaatc acgcaaagga tatcaa 26 33 23 DNA Artificial Completely Synthesized 33 atygatattr catcrttaac aag 23 34 26 DNA Artificial Completely Synthesized 34 aaaaycatct gaytaattat tctata 26 35 22 DNA Artificial Completely Synthesized 35 tcacaataat ttaaaatgct ct 22 36 23 DNA Artificial Completely Synthesized 36 gtcgtcaata gcattaataa tac 23 37 22 DNA Artificial Completely Synthesized 37 gtagccaata gcgttaataa ta 22 38 23 DNA Artificial Completely Synthesized 38 gatgctaatg atatatttcc ata 23 39 23 DNA Artificial Completely Synthesized 39 acrttctatt gtgaaggtgc ytc 23 40 21 DNA Artificial Completely Synthesized 40 atatttcaag cyccatagta g 21 41 18 DNA Artificial Completely Synthesized 41 gagtgcccta atccagtg 18 42 20 DNA Artificial Completely Synthesized 42 ctgtgttctt aggtattatg 20 43 22 DNA Artificial Completely Synthesized 43 attgcttacg gaggtgattt tg 22 44 21 DNA Artificial Completely Synthesized 44 atcatttcca tgtagagttg c 21 45 24 DNA Artificial Completely Synthesized 45 tcttytgcac cctartcyat ttga 24 46 21 DNA Artificial Completely Synthesized 46 gtycaattct accttctatg a 21 47 21 DNA Artificial Completely Synthesized 47 gacttgraga ggtacrtttt c 21 48 21 DNA Artificial Completely Synthesized 48 gacttggaga agtacatttt c 21 49 21 DNA Artificial Completely Synthesized 49 gcattrcttc tctgaatgaa t 21 50 22 DNA Artificial Completely Synthesized 50 agttagttgt aatccactat ac 22 51 22 DNA Artificial Completely Synthesized 51 attttgcgat caatatacac at 22 52 20 DNA Artificial Completely Synthesized 52 gatgatgatg atgatgatga 20 53 22 DNA Artificial Completely Synthesized 53 caattatayc ctatttactc aa 22 54 22 DNA Artificial Completely Synthesized 54 ttgagtaaat aggrtataat tg 22 55 31 DNA Artificial Completely Synthesized 55 tttttaatta accyagaatc gggtaatttt t 31 56 21 DNA Artificial Completely Synthesized 56 ttacccgatt ctrggttaat t 21 57 51 DNA Artificial Completely Synthesized 57 tttttttttt ttttttctra cagctttgrc aagttttttt tttttttttt t 51 58 21 DNA Artificial Completely Synthesized 58 aaacttgyca aagctgtyag a 21 59 19 DNA Artificial Completely Synthesized 59 tatcagyccc attgcctat 19 60 19 DNA Artificial Completely Synthesized 60 ataggcaatg ggrctgata 19 61 20 DNA Artificial Completely Synthesized 61 cccyttaact gcgaataaac 20 62 20 DNA Artificial Completely Synthesized 62 gtttattcgc agttaarggg 20 63 59 DNA Artificial Completely Synthesized 63 tttttttttt tttttttttt cctatttgct acaacagtgt tttttttttt ttttttttt 59 64 19 DNA Artificial cactgttgtagcaaatagg 64 cactgttgta gcaaatagg 19 65 20 DNA Artificial Completely Synthesized 65 argacgtcac ctctaaacga 20 66 20 DNA Artificial Completely Synthesized 66 tcgtttagag gtgacgtcyt 20 67 23 DNA Artificial Completely Synthesized 67 cttgttaayg atgyaatatc rat 23 68 23 DNA Artificial Completely Synthesized 68 atygatattr catcrttaac aag 23 69 44 DNA Artificial Completely Synthesized 69 tttttttttt tcaaatrgay tagggtgcar aagatttttt tttt 44 70 24 DNA Artificial Completely Synthesized 70 tcttytgcac cctartcyat ttga 24 71 22 DNA Artificial Completely Synthesized 71 gtatagtgga ttacaactaa ct 22 72 22 DNA Artificial Completely Synthesized 72 agttagttgt aatccactat ac 22 73 22 DNA Artificial Completely Synthesized 73 caattatayc ctatttactc aa 22 74 20 DNA Artificial Completely Synthesized 74 gatgatgatg atgatgatga 20 

What is claimed is:
 1. A method of illumination in a biochip reader comprising the steps of: providing an illumination source; providing a glass substrate having opposing sides and said glass substrate carrying a bioarray; directing light from said illumination source to opposing sides of said glass substrate by a pair of optical fiber bundles; each of said optical fiber bundles including a plurality of optical fibers; forming an optical fiber fan of each of said optical fiber bundles, each said optical fiber defining a line of optical fiber faces of said plurality of optical fibers; and providing a respective divergent diffuser proximate to each line of optical fiber faces for coupling and diffusing light substantially evenly through said opposing sides of said glass substrate to illuminate said bioarray carried by said glass substrate.
 2. A method of illumination in a biochip reader as recited in claim 1 wherein the step of forming said optical fiber fan of each of said optical fiber bundles, each said optical fiber fan defining said line of optical fiber faces of said plurality of optical fibers includes the steps of forming said optical fiber fan being one fiber thick and defining said line of optical fiber faces of said plurality of optical fibers.
 3. A method of illumination in a biochip reader as recited in claim 1 wherein the step of directing said light to opposing sides of said glass substrate by said pair of optical fiber bundles further includes the steps of providing a second pair of optical fiber bundles; and directing said light to opposing ends of said glass substrate.
 4. A method of illumination in a biochip reader as recited in claim 1 wherein the step of providing a respective divergent diffuser proximate to each line of optical fiber faces for coupling and diffusing light substantially evenly through said opposing sides of said glass substrate to illuminate said bioarray supported by said glass substrate includes the steps of providing said respective divergent diffuser formed of a silicon material.
 5. A method of illumination in a biochip reader as recited in claim 1 wherein the step of providing a respective divergent diffuser proximate to each line of optical fiber faces for coupling and diffusing light substantially evenly through said opposing sides of said glass substrate to illuminate said bioarray supported by said glass substrate includes the steps providing said glass substrate used as a secondary laser light guide.
 6. A method of illumination in a biochip reader as recited in claim 1 wherein the step of providing a respective divergent diffuser proximate to each line of optical fiber faces for coupling and diffusing laser light substantially evenly through said opposing sides of said glass substrate to illuminate said bioarray supported by said glass substrate includes the steps using each optical fiber face for light transfer at a restricted angle.
 7. A method of illumination in a biochip reader as recited in claim 1 wherein said step of using each optical fiber face for laser light transfer at a restricted angle in a range between 55° to 60°.
 8. A method of illumination in a biochip reader as recited in claim 1 wherein said step of forming said optical fiber fan of each of said optical fiber bundles, each said optical fiber fan defining said line of optical fiber faces of said plurality of optical fibers includes the steps of forming said optical fiber fan of each of said optical fiber bundles on a positioner; said positioner positioning said glass substrate carrying said bioarray.
 9. A method of illumination in a biochip reader as recited in claim 1 wherein said step of providing a glass substrate having opposing sides and said glass substrate carrying a bioarray includes the steps of providing a glass holder for supporting said glass substrate carrying said bioarray; said glass holder including a plastics springs member in spring contact engagement with said glass substrate for positioning said bioarray in a focal plane.
 10. Apparatus for bioarray illumination in a biochip reader comprising: an illumination source; a glass substrate having opposing sides and said glass substrate carrying a bioarray; a pair of optical fiber bundles directing said light from said illumination source to opposing sides of said glass substrate; each of said optical fiber bundles including a plurality of optical fibers; a pair of optical fiber fans formed by said optical fiber bundles proximate to opposing sides of said glass substrate carrying said bioarray each said optical fiber fan defining a line of optical fiber faces of said plurality of optical fibers; and a respective divergent diffuser proximate to each said line of optical fiber faces for coupling and diffusing laser light substantially evenly through said opposing sides of said glass substrate to illuminate said bioarray carried by said glass substrate.
 11. Apparatus for bioarray illumination as recited in claim 10 wherein said glass substrate functions as a secondary laser light guide.
 12. Apparatus for bioarray illumination as recited in claim 10 wherein each said optical fiber fan is one fiber thick.
 13. Apparatus for bioarray illumination as recited in claim 10 wherein each said divergent diffuser is formed of a silicon material.
 14. Apparatus for bioarray illumination as recited in claim 10 wherein said illumination source includes one of a low power non-collimated laser diode or a light emitting diode (LED).
 15. Apparatus for bioarray illumination as recited in claim 14 wherein said low power non-collimated laser diode has a power rating in a range between 3 mW through 5 mW.
 16. Apparatus for bioarray illumination as recited in claim 9 wherein said illumination source includes a plurality of light sources; one respective light source of said plurality of light sources coupled to each optical fiber bundle.
 17. Apparatus for bioarray illumination as recited in claim 9 wherein said non-collimated laser source providing laser light includes a non-collimated laser source providing laser light at a set wavelength in a range between 470 nm and 650 nm.
 18. Apparatus for bioarray illumination as recited in claim 9 includes a reflector positioned proximate to another side of said glass substrate spaced apart from said fiber optic fans; said reflector for reflecting outgoing light back into said glass substrate. 